Method and apparatus for providing input EMI filtering in power supplies

ABSTRACT

A power supply electromagnetic interference (EMI) filter circuit and technique. In one embodiment, a method of filtering EMI in a power supply includes rectifying an AC signal from an AC source, smoothing the rectified AC signal with a bulk storage capacitor to provide a DC output as an input to a power conversion circuit and filtering the EMI generated by the power conversion circuit from reaching the AC source by using the bulk capacitor and one or more inductors in combination with the AC source capacitance as an EMI filter. In one embodiment the method also includes the use of one or more of the inductors as a fusing element.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to power supplies and, morespecifically, the present invention relates to a switched mode powersupply with an input electromagnetic interference (EMI) filter circuit.

2. Background Information

Electronic devices use power to operate. Switched mode power supplies oradapters are widely used to power electronic products as well as chargebatteries used to power mobile products such as for example wirelessphones, palm top computers, toys, etc. Switched mode power suppliesgenerate EMI, which must be filtered to allow the power supply to meetnational and international standards stipulating acceptable levels ofEMI. This requires that the switched mode power supply includecomponents at the input of the power supply that filter EMI in order tomeet these standards. Furthermore, an input fuse is required to meetnational and international safety standards.

Known power supply techniques employ input EMI filter circuits ofvarying complexity. The simplest form of input EMI filter is known as api filter and is used in low-power power supplies to reduce power supplycost. The fuse is a separate component, which is typically eitherdesigned solely for use as a fuse or as a resistor specifically designedto meet national and international safety standards as a fusiblecomponent.

SUMMARY OF THE INVENTION

A power supply input EMI filter circuit is disclosed. In one embodiment,a method of filtering EMI in a power supply includes rectifying an ACsignal with a rectifier, smoothing the rectified signal with a bulkstorage capacitor to provide a DC output as an input to a powerconversion circuit and filtering the EMI generated by the powerconversion circuit from reaching the AC source by using the bulkcapacitor and one or more inductors in combination with the AC sourcecapacitance as an EMI filter. In one embodiment the method also includesthe use of one or more of the inductors as a fusing element to meetsafety requirements. Additional features and benefits of the presentinvention will become apparent from the detailed description and figuresset forth below.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention detailed illustrated by way of example and notlimitation in the accompanying figures.

FIG. 1 is a schematic illustrating a power supply input circuitincluding a fuse and input EMI filter circuit.

FIG. 2 is a schematic illustrating one embodiment of a power supply witha simplified input EMI filter circuit and fuse in accordance with theteachings of the present invention.

FIG. 3 is a schematic illustrating another embodiment of a power supplywith a simplified input EMI filter and fuse circuit in accordance withthe teachings of the present invention.

FIG. 4A provides an illustration of one embodiment of a full waverectifier utilizing a diode bridge in accordance with the teachings ofthe present invention.

FIG. 4B provides an illustration of one embodiment of a half waverectifier utilizing a single diode on one of the rails in accordancewith the teachings of the present invention.

FIG. 4C provides an illustration of one embodiment of a half waverectifier utilizing a single diode on each of the rails in accordancewith the teachings of the present invention.

FIG. 4D provides an illustration of one embodiment of a half waverectifier utilizing a plurality of diodes on at least one of the railsin accordance with the teachings of the present invention.

FIG. 5 is a schematic illustrating yet another embodiment of a powersupply with a simplified input EMI filter and fuse circuit in accordancewith the teachings of the present invention.

FIG. 6 is a schematic illustrating still another embodiment of a powersupply with a simplified input EMI filter and fuse circuit in accordancewith the teachings of the present invention.

DETAILED DESCRIPTION

A novel technique to reduce the cost of input EMI filter circuitry inswitched mode power supplies is disclosed. In the following description,numerous specific details are set forth in order to provide a thoroughunderstanding of the present invention. It will be apparent, however, toone having ordinary skill in the art that the specific detail need notbe employed to practice the present invention. In other instances,well-known materials or methods have not been described in detail inorder to avoid obscuring the present invention.

In one embodiment, the present invention provides a simplified input EMIcircuit, which therefore reduces the cost and complexity of input EMIfilter circuitry and the fuse function.

To illustrate, FIG. 1 shows a schematic of a power supply input stageincluding a fuse 101, a rectifier circuit 100 and EMI filter circuitryincluding capacitors 103 and 104 and an inductor 105. The input EMIfilter circuitry is coupled in a configuration that is known as a pifilter, which can be appreciated to one skilled in the art. As can beappreciated by one skilled in the art, the rectifier circuit 100 can beeither a well-known full or half wave rectifier circuit. If a full waverectifier circuit is used, the rectification bridge of rectifier circuit100 can be constructed using either discrete diodes or a singlecomponent bridge rectifier. If a half wave rectifier circuit is used,the rectifier circuit 100 can be constructed using a single diode ormultiple diodes coupled in series. The latter construction is used incertain embodiments to reduce EMI and or to increase the amount of inputvoltage surges that rectifier circuit 100 can withstand, as will beappreciated to one skilled in the art.

The circuitry shown in FIG. 1 has an AC source 102 at the input andprovides a rectified and smoothed or filtered DC output voltage at DCoutput 106. Such a configuration is typical of low power AC to DC powersupply circuits such as those employed in low power (<10 Watts output)adapters and chargers for consumer electronics items and the like. Aswell as forming part of the pi filter, capacitors 103 and 104 alsoprovide bulk storage of charge derived from the AC source 102 when thevoltage across the AC source 102 is greater than the DC voltage acrosscapacitors 103 and 104. When this condition is met, current flows fromthe AC source 102 through capacitors 103 and 104. The charge thus storedon capacitors 103 and 104 provides a relatively stable DC output voltageat DC output 106 as required for efficient operation of a powerconversion circuit that is to be coupled to receive the DC outputvoltage at DC output 106.

The fuse 101 shown in FIG. 1, which is coupled between AC source 102 andrectifier circuit 100 is a fusible resistor. In order for a resistor tofulfill the international standards required of a fuse component, theresistor is normally of a wore wound construction and covered in a flameretardant or heatshrink material that prevents pieces of the resistorbeing scattered when the fuse 101 is blown during a fault condition. Theposition of the fuse 101 is also important to ensure compliance of thepower supply with international safety standards.

To comply with international safety standards, the fuse 101 must bepositioned such that it becomes an open circuit in the event of anabnormally high current being drawn from AC source 102 due to a fault onany component in the rectifier circuit 100, EMI filter consisting ofcomponents 103, 104 and 105 or any component in the power supply circuitcoupled to DC output 106. FIG. 1 therefore shows the most obviousposition for fuse 101 to ensure that it limits an abnormal current inthe case of a fault in any component coming after fuse 101.

FIG. 2 shows a schematic illustrating one embodiment of a power supplyinput stage utilized in a power supply in accordance with the teachingsof the present invention. In the illustrated embodiment, an AC signalfrom an AC source 102 is rectified by rectifier circuit 200 and is thensmoothed at DC output 106 by capacitor 203. The circuit shown is asimplification of that shown in FIG. 1 through the elimination of thefuse 101 and also one of the bulk storage capacitors 103 and 104. In thecircuit embodiment of FIG. 2, the input fuse function is provided byinductor 202, which also forms part of an EMI filter as described later.As can be appreciated to one skilled in the art, typical input inductorcomponents used in power supplies, such as for example below 10 Wattsoutput, are typically constructed of a fine wire wound on a ferritecore. As such the construction is similar to the fusible resistor 101described above. As such, by the correct choice of wire gauge(diameter), inductor 202 can be designed to become an open circuit underspecific conditions of abnormal current flow such as those due to afault in one of the power supply components. In one embodiment, theposition of inductor 202, in common with the fuse 101 in FIG. 1, is onthe AC source 102 side of the rectifier circuit 200 to ensure circuitprotection under any of the abnormal current conditions as describedearlier.

The EMI filter configuration of the circuit in FIG. 2 forms a pi filterwith the single bulk storage capacitor 203, inductor 202 and AC sourcecapacitance 201 of AC source 102. It is appreciated that AC sourcecapacitance 201 is a distributed source capacitance of AC source 102,rather than a specific component. This AC source capacitance 201 ispresent in every AC source 102 and is represented by an equivalentcapacitance in the equipment used to make EMI measurements. Thisequipment is called a Line Impedance Stabilization Network (LISN), aswill be familiar to one skilled in the art. The AC source or LISNcapacitance can therefore be specifically used to form a pi filter withthe simplified input circuitry of FIG. 2 in accordance with theteachings of the present invention. Since EMI measurements are madeunder standardized conditions of input cable length and LISN circuitry,the AC source capacitance 201 is deterministic and provides repeatablemeasurements to ensure consistent EMI filter performance.

As shown in the depicted embodiment, rectifier circuit 200 is coupledbetween inductor 202 and capacitor 203. In one embodiment, thecapacitance value of capacitor 203 is not necessarily equal to the valueof capacitance 104 of FIG. 1. In the depicted embodiment, capacitor 203is a single capacitor and is adapted to provide the bulk storagefunction and is therefore usually a larger value of capacitance valuethan that of capacitor 104 to achieve the same average DC output voltageat DC output 106. However, despite typically being a larger capacitor,the elimination of one bulk storage capacitor typically provides asignificant cost saving over the configuration in FIG. 1 since the costof each capacitor component is strongly influenced by the packagingitself, which is reduced using a single component. Furthermore, theelimination of one bulk storage capacitor reduces the cost of circuitassembly in production by reducing component count. In one embodiment,inductor 202 also does not necessarily the same inductance value asinductor 105 and is chosen in each case to optimize the pi filterperformance with the AC source capacitance 201 and bulk storagecapacitor 203. In operation, the rectified and smoothed or filtered DCvoltage at DC output 106 is received by power conversion circuit 208,which generates an output voltage at power conversion circuit output210. In one embodiment, power conversion circuit 208 is a switched modepower converter and the EMI filter circuit of FIG. 2 is employed tofilter the EMI in accordance with the teaching of the present invention.

FIG. 3 shows a schematic illustrating another embodiment of a powersupply input stage employed in a power supply in accordance with theteachings of the present invention. The circuit shown is again asimplification of that shown in FIG. 1 through the elimination of thefuse 101 and also one of the bulk storage capacitors 103 and 104. In thecircuit of FIG. 3, the input fuse function is provided by inductor 302,which also forms part of the EMI filter.

In this configuration however, the inductor 302 is placed on the outputside of the rectifier circuit 300. That is, rectifier circuit 300 isbetween AC source 102 and inductor 302. In one embodiment, this places alimitation on the type of input rectifier circuit 300 that can be usedif the inductor is also required to perform the fuse function. Thislimitation arises since connection of inductor 302 can only provide afuse function in compliance with international safety standardsdescribed earlier if the input rectifier circuit 300 is a half waverectifier circuit. As can be appreciated by one skilled in the art, ifinput rectifier circuit 300 is a full wave bridge rectifier circuit, theshort circuit failure of any one of the diodes in the rectificationbridge will cause abnormally high current to be drawn from AC source 102without this current flowing through inductor 302. In one embodiment,the circuit shown in FIG. 3 is therefore limited to use when inputrectifier circuit 300 is a half wave rectifier circuit if the inductoris also required to function as a fuse.

To illustrate, FIGS. 4A, 4B, 4C and 4D provide various exampleschematics of various embodiments of rectifiers that may be utilized inaccordance with the teachings of the present invention. In particular,FIG. 4A provides an illustration of one embodiment of a full waverectifier utilizing a diode bridge. FIG. 4B provides an illustration ofone embodiment of a half wave rectifier utilizing a single diode on oneof the rails. FIG. 4C provides an illustration of one embodiment of ahalf wave rectifier utilizing a single diode on each of the rails. FIG.4D provides an illustration of one embodiment of a half wave rectifierutilizing a plurality of diodes on at least one of the rails. It isappreciated that other suitable variations of the schematics illustratedin FIGS. 4A, 4B, 4C and 4D may be utilized in accordance with theteachings of the present invention. Any one of the rectifier circuitsshown could be used in the circuits of FIG. 2, 3 or the circuitsdescribed below though their application is not limited to only thoseconfigurations shown in FIGS. 4A, 4B, 4C and 4D.

As illustrated in FIGS. 4B, 4C and 4D, embodiments of the half waverectifier circuit can be constructed using a single diode or multiplediodes coupled in series. When using multiple diodes, one or more diodescan be connected on either or both AC input rails. Using one or morediodes on both rails of the AC input reduces EMI by blocking the EMIgenerated by the power conversion circuit from being coupled to the ACsource on both rails during times when the diodes are not conducting.

As will be appreciated by one skilled in the art, in one embodiment, theconfiguration of FIG. 3 can be used with rectifier circuit 300 as a fullwave rectifier circuit, such as for example the rectifier illustrated inFIG. 4A, if a separate fuse component is used coupled in series with theAC source 102 on the input side of rectifier circuit 300. In thisembodiment, inductor 302 no longer provides the fuse function and thecircuit complies with international safety standards.

Referring back to the embodiment of FIG. 3, an AC signal is provided byAC source 102 and is rectified by rectifier circuit 300 and smoothed bycapacitor 303 such that a rectified and smoothed or filtered DC signalis generated at DC output 106. The rectified and smoothed DC signal atDC output 106 is coupled to be received by power conversion circuit 208such that an output is generated at power conversion output 210. In oneembodiment, power conversion circuit 208 is a switched mode powerconverter.

The EMI filter function in the embodiment of FIG. 3 is made up ofinductor 302, bulk storage capacitor 303 and AC source capacitance 201of AC source 102. In common with the embodiment of FIG. 2, the AC sourceor LISN capacitance is used to form a pi filter with the simplifiedinput circuitry of FIG. 3. Other benefits of the simplified inputcircuitry of FIG. 3 are common with those of the circuit illustrated inFIG. 2 as described previously.

FIG. 5 shows a schematic illustrating yet another embodiment of a powersupply input stage of a power supply in accordance with the teachings ofthe present invention. In the embodiment depicted in FIG. 5, the generalconfiguration and functionality share similarities with the embodimentshown and described with respect to FIG. 2. An AC signal is output by ACsource 102 and it is rectified by rectifier 500 and smoothed or filteredby capacitor 503 to provide a DC signal at DC output 106 at capacitor503. Power conversion circuit 208 receives the rectified and smoothed DCsignal at DC output 106 such that an output is provided at powerconversion circuit output 210.

Two inductors 502 and 504, however, have replaced the input inductor 202of the embodiment of FIG. 2. In the illustrated embodiment, inductors502 and 504 are coupled between AC source 102 and rectifier circuit 500.In one embodiment, the total inductance of inductors 502 and 504 is notnecessarily equal to the inductance of inductor 202. For instance, inone embodiment, one of the inductors 502 and 504 could be designedspecifically to have different impedance versus frequencycharacteristics than the other in order to filter specific EMIfrequencies more efficiently. In this embodiment either one or both ofinductors 502 and 504 can act as a fuse. Typically the lowest costsolution is to design only one of the inductors 502 and 504 to act as afuse in order that only one has the flame retardant or heatshrinkcovering to comply with international safety standards as a fusecomponent. This can be accomplished, for example, by using a thinnerwire on the inductor that is to function as fuse than the wire used onthe other inductor.

FIG. 6 shows a schematic illustrating still another embodiment of apower supply input stage used in a power supply in accordance with theteachings of the present invention. In FIG. 6, the general configurationand functionality share similarities with the circuit shown in FIG. 3.In the depicted embodiment, an AC signal is generated by AC source 102and rectifier circuit 600 rectifies the AC signal and capacitor 603smoothes the signal such that a rectified and smoothed or filtered DCsignal is generated at DC output 106 at capacitor 603. The rectified andsmoothed DC signal at DC output 106 is received by power conversioncircuit 208 such that an output is generated at power conversion circuitoutput 210.

The input inductor 302 of embodiment FIG. 3, however, has replaced bytwo inductors 602 and 604. As shown, rectifier circuit 600 is coupledbetween AC source 102 and inductors 602 and 604. In one embodiment, thetotal inductance of inductors 602 and 604 is not necessarily equal tothe inductance of inductor 302. For instance, in one embodiment, one ofthe inductors 602 and 604 could be designed specifically to havedifferent impedance versus frequency characteristics than the other inorder to filter specific EMI frequencies more efficiently. In thisembodiment either one or both of inductors 602 and 604 can act as afuse. Typically the lowest cost solution is to design only one of theinductors 602 and 604 to act as a fuse in order that only one of theinductors 602 or 604 includes flame retardant or heatshrink covering tocomply with international safety standards as a fuse component.

In one embodiment, the circuit embodiment of FIG. 6 shares similarlimitations as that of the circuit embodiment of FIG. 3 in terms of theinput rectifier circuit 600. For instance, in one embodiment, rectifiercircuit 600 must be a half wave rectifier circuit in order for the useof either inductor 602 or 604 as a fuse to meet international safetystandards as previously described. Rectifier circuit 600 can, however,be a full wave rectifier circuit if a separate fuse component is coupledbetween the AC source 102 and the input to rectifier circuit 600.

In the foregoing detailed description, the present invention has beendescribed with reference to specific exemplary embodiments thereof. Itwill, however, be evident that various modifications and changes maybemade thereto without departing from the broader spirit and scope of thepresent invention. The present specification and figures are accordinglyto be regarded as illustrative rather than restrictive.

What is claimed is:
 1. A power supply input electromagnetic interference(EMI) filter circuit, comprising: an inductor to be coupled to a LineImpedance Stabilization Network (LISN) having a LISN capacitancerepresentative of an alternating current (AC) source capacitance; arectifier having an input coupled to the inductor, the inductor to becoupled between the LISN and the rectifier; and a capacitor coupled toan output of the rectifier such that an EMI pi filter is formed with theLISN capacitance, the inductor and the capacitor.
 2. The power supplyEMI filter circuit of claim 1 wherein the capacitor is adapted toprovide bulk storage for a direct current (DC) input of a power supplyconversion circuit to be coupled to the capacitor.
 3. The power supplyEMI filter circuit of claim 2 wherein the power conversion circuit isadapted to provide an output power of less than approximately ten Watts.4. The power supply EMI filter circuit of claim 2 wherein the capacitorthat provides the bulk storage for the DC input of the power supplyconversion circuit consists of a single capacitor.
 5. The power supplyEMI filter circuit of claim 1 wherein the rectifier is half waverectifier circuit.
 6. The power supply EMI filter circuit of claim 5wherein the half wave rectifier circuit includes a plurality of inputsand a corresponding plurality of outputs, wherein the half waverectifier circuit comprises one or more diodes coupled between each ofthe inputs and the corresponding outputs of the half wave rectifiercircuit.
 7. The power supply EMI filter circuit of claim 1 wherein therectifier is a full wave rectifier circuit.
 8. The power supply EMIfilter circuit of claim 1 wherein the inductor is adapted to function asa fuse to limit an abnormal amount of current flow.
 9. The power supplyEMI filter circuit of claim 8 wherein the inductor is covered with aflame retardant material.
 10. The power supply EMI filter circuit ofclaim 8 wherein the inductor is covered with a heatshrink material. 11.A power supply input electromagnetic interference (EMI) filter circuit,comprising: a rectifier having an input to be coupled to a LineImpedance Stabilization Network (LISN) having a LISN capacitancerepresentative of an alternating current (AC) source capacitance; aninductor having a first terminal coupled to an output of the rectifier,the rectifier to be coupled between the LISN and the first terminal ofthe inductor; and a capacitor coupled to a second terminal of theinductor such that an EMI pi filter is formed with the LISN capacitance,the inductor and the capacitor.
 12. The power supply EMI filter circuitof claim 11 wherein the capacitor is adapted to provide bulk storage fora direct current (DC) input of a power supply conversion circuit to becoupled to the capacitor.
 13. The power supply EMI filter circuit ofclaim 12 wherein the power conversion circuit is adapted to provide anoutput power of less than approximately ten Watts.
 14. The power supplyEMI filter circuit of claim 12 wherein the capacitor that provides thebulk storage for the DC input of the power supply conversion circuitconsists of a single capacitor.
 15. The power supply EMI filter circuitof claim 11 wherein the rectifier is half wave rectifier circuit. 16.The power supply EMI filter circuit of claim 15 wherein the half waverectifier circuit includes a plurality of inputs and a correspondingplurality of outputs, wherein the half wave rectifier circuit comprisesone or more diodes coupled between each of the inputs and thecorresponding outputs of the half wave rectifier circuit.
 17. The powersupply EMI filter circuit of claim 11 wherein the rectifier is a fullwave rectifier circuit.
 18. The power supply EMI filter circuit of claim11 wherein the inductor is adapted to function as a fuse to limit anabnormal amount of current flow.
 19. The power supply EMI filter circuitof claim 18 wherein the inductor is covered with a flame retardantmaterial.
 20. The power supply EMI filter circuit of claim 18 whereinthe inductor is covered with a heatshrink material.
 21. A power supplyinput electromagnetic interference (EMI) filter circuit, comprising: afirst inductor to be coupled to a first line of a Line ImpedanceStabilization Network (LISN) having a LISN capacitance representative ofan alternating current (AC) source capacitance; a second inductor to becoupled to a second line of the LISN; a rectifier having first andsecond inputs coupled to the first and second inductors, respectively,the first and second inductors to be coupled between the LISN and therectifier; and a capacitor coupled to an output of the rectifier suchthat an EMI filter is formed with the LISN capacitance, the first andsecond inductors and the capacitor.
 22. The power supply EMI filtercircuit of claim 21 wherein the capacitor is adapted to provide bulkstorage for a direct current (DC) input of a power supply conversioncircuit to be coupled to the capacitor.
 23. The power supply EMI filtercircuit of claim 22 wherein the power conversion circuit is adapted toprovide an output power of less than approximately ten Watts.
 24. Thepower supply EMI filter circuit of claim 22 wherein the capacitor thatprovides the bulk storage for the DC input of the power supplyconversion circuit consists of a single capacitor.
 25. The power supplyEMI filter circuit of claim 21 wherein the rectifier is half waverectifier circuit.
 26. The power supply EMI filter circuit of claim 25wherein the half wave rectifier circuit includes a plurality of inputsand a corresponding plurality of outputs, wherein the half waverectifier circuit comprises one or more diodes coupled between each ofthe inputs and the corresponding outputs of the half wave rectifiercircuit.
 27. The power supply EMI filter circuit of claim 21 wherein therectifier is a full wave rectifier circuit.
 28. The power supply EMIfilter circuit of claim 21 wherein at least one or more of the first andsecond inductors are adapted to function as at least one or more fusesto limit an abnormal amount of current flow.
 29. The power supply EMIfilter circuit of claim 28 wherein the at least one or more of the firstand second inductors that are adapted to function as the at least one ormore fuses to limit the abnormal amount of current flow are covered witha flame retardant material.
 30. The power supply EMI filter circuit ofclaim 28 wherein the at least one or more of the first and secondinductors that are adapted to function as the at least one or more fusesto limit the abnormal amount of current flow are covered with aheatshrink material.
 31. A power supply input electromagneticinterference (EMI) filter circuit, comprising: a rectifier having aninput to be coupled to a Line Impedance Stabilization Network (LISN)having a LISN capacitance representative of an alternating current (AC)source capacitance; a first inductor having a first terminal coupled toa first output of the rectifier; a second inductor having a firstterminal coupled to a second output of the rectifier, the rectifier tobe coupled between the LISN and the first and second inductors; and acapacitor coupled between a second terminal of the first inductor and asecond terminal of the second inductor such that an EMI filter is formedwith the LISN capacitance, the first and second inductors and thecapacitor.
 32. The power supply EMI filter circuit of claim 31 whereinthe capacitor is adapted to provide bulk storage for a direct current(DC) input of a power supply conversion circuit to be coupled to thecapacitor.
 33. The power supply EMI filter circuit of claim 32 whereinthe power conversion circuit is adapted to provide an output power ofless than approximately ten Watts.
 34. The power supply EMI filtercircuit of claim 32 wherein the capacitor that provides the bulk storagefor the DC input of the power supply conversion circuit consists of asingle capacitor.
 35. The power supply EMI filter circuit of claim 31wherein the rectifier is half wave rectifier circuit.
 36. The powersupply EMI filter circuit of claim 35 wherein the half wave rectifiercircuit includes a plurality of inputs and a corresponding plurality ofoutputs, wherein the half wave rectifier circuit comprises one or morediodes coupled between each of the inputs and the corresponding outputsof the half wave rectifier circuit.
 37. The power supply EMI filtercircuit of claim 31 wherein the rectifier is a full wave rectifiercircuit.
 38. The power supply EMI filter circuit of claim 31 wherein theinductor is adapted to function as a fuse to limit an abnormal amount ofcurrent flow.
 39. The power supply EMI filter circuit of claim 38wherein the inductor is covered with a flame retardant material.
 40. Thepower supply EMI filter circuit of claim 38 wherein the inductor iscovered with a heatshrink material.
 41. A method, comprising: rectifyingan alternating current (AC) signal from a Line Impedance StabilizationNetwork (LISN) having a LISN capacitance representative of an AC sourcecapacitance; filtering the rectified AC signal with a bulk storagecapacitor to provide a DC signal to an input of a power conversioncircuit; and filtering the electromagnetic interference (EMI) generatedby the power converter circuit with an EMI filter that includes the LISNcapacitance representative of the AC source capacitance, one or moreinductors and the bulk storage capacitor.
 42. The method of claim 41wherein rectifying the AC signal comprises full wave rectifying the ACsignal with a full wave rectifier.
 43. The method of claim 41 whereinrectifying the AC signal from the LISN comprises half wave rectifyingthe AC signal.
 44. The method of claim 41 further comprising limiting anabnormal amount of current from flowing with at least one of said one ormore inductors that are included in the EMI filter.
 45. The method ofclaim 44 further comprising covering the at least one of said one ormore inductors with a flame retardant material.
 46. The method of claim44 further comprising covering the at least one of said one or moreinductors with a heatshrink material.